Electric valve circuit



Feb. 18, 1941. L Y, JR l 7 2,232,541

ELECTRIC VALVE CIRCUIT Filed larch 31, 1938 Inventor His Attorney.

Patented Feb. 18, 1941 UNITED STATES ELECTRIC VALVE CIRCUIT Louis G. Levoy, Jr Schenectady, N. Y assignor to General Electric Company, a corporation of New York Application March 31,1938, SerialNo. 199,156

11 Cla ms.

My invention relates to electric translatin apparatus and more particularly to electric valve circuits.

In electric valve translating apparatus, it is frequently desirable to control the electric valves to effect periodic energization of an associated load circuit or to transmit a predetermined amount of energy to the load circuit during an accurately determinable interval of time. For example, in electric valve circuits employed in welding operations, it is desirable to use the same control circuits in spot welding, interrupted-spot and seam or line welding operations. In many of these electric valve welding systems, the control of the electric valves has been effected by use of an electric valve timing circuit which generates an electrical timing quantity such as a control voltage of predetermined periodicity or duration. The generating circuit may be or the type employing a source of direct current, a capacitance and an electric valve which discharges the capacitance which has been previously charged from the direct current source. The welding cycle, 01 course, is controllable by adjustment of for use in spot welding and interrupted-spot welding operations, it has been found feasible to employ as additional circuit, sometimes referred to as a lockout circuit, which renders ineffective circuit. There has been evidenced a decided need or inoperative the timing circuit at the expiration oi an accurately definable interval of time. It is important that this lockout circuit operate to effect this control irrespective of the magnitude of the control voltage produced by the timing for improved circuits of this nature.

It is an object of my invention to provide a new I and improved electric valve circuit.

It is another object or my invention to provide a new and improved electric valve circuit whereby ('01. sac-27) whereby the period of energization of a load circuit is accurately controllable.

It is a still further object of my invention to provide a new and improved electric valve circuit for controlling electric translating apparatus in which a load circuit is periodically energized during a predetermined interval of time and in which the ratio of the intervals of energization to the intervals of deenergization is accurately controllable.

In accordance with the illustrated embodiment of my invention, I provide an improved electric valve circuit particularly adaptable for use in connection with electric valve translating apparatus for welding operations; such as spot welding, interrupted-spot and seam welding operations. Electric valve apparatus is connected between an alternating current supply circuit and the welding circuit to transmitcurrent thereto. An electric circuit is employed for producing a timing quantity, such as an impulse of voltage or a periodic voltage, to control the electric valve apparatus to eifect a single energization of the welding circuit or to efiect a predetermined number of consecutive energizations of the welding circuit. The single energization or the consecutive energizations of the load circuit may each correspond toa fraction of a half cycle of voltage of the associated alternating current supply circuit, or

may correspond to a complete half cycle of the voltage of the alternating current supply circuit, or may correspond to a predetermined number of such whole or fractional half cycles. The timing circuit comprises electric discharge devices which determine the time of initiation of the control voltage and determines the ratio of the interval of conduction to the interval of nonconduction of the electric valve apparatus. In order to assure a single energization of the load circuit or a predetermined number of consecutive energiza- 'tions of the load circuit during an interval 'of time, I provide a lockout circuit for the timing circuit which impresses a negative voltage on a control member of one or more of the electric discharge devices in the timing circuit at the expiration of the desired interval. This lockout circuit comprises anv electric discharge device having a control member. The electric discharge device in the lockout circuit is arranged to impress a negative unidirectional biasing potential on thecontrol member of one or more of the electric discharge devices in the timing circuit.

I provide a control circuit for energizing the control member of the electric discharge device in the lockout circuit. This control circuit comprises means for impressing on the control memher a negative unidirectional biasing potential tending to maintain the discharge device nonconductive and includes an additional circuit which operates independently of the magnitude of the control voltage produced by the timing circuit to control accurately the time at which the electric discharge device in the lockout circuit is rendered conductive. This latter circuit comprises a serially connected capacitance, a rectifier which is energized from the alternating current supply circuit, and a controlled electric valve which is energized in response to the control voltage produced by the timing circuit. A variable impedance element is connected in series relation with the capacitance, the rectifier and the controlled electric valve to control the rate at which the charge is established on the capacitance and hence to control the timing interval. Since the rectifier is energized from the alternating current circuit, the incremental charge established on the capacitance is independent of the magnitude of the periodic quantity generated by the timing circuit, permitting a precise control of the timing interval.

For a better understanding of my invention, reference may be had to the following description taken in connection with the accompanying drawing, and its scope will be pointed out in the appended claims. The single figure of the accompanying drawing diagrammatically illustrates an embodiment of my invention as applied to an electric valve welding circuit.

Referring now to the single figure of the drawing, I have there diagrammatically illustrated my invention as applied to an electric circuit for effecting energization of a Welding circuit I from an alternating current supply circuit 2, through a transformer 3 and electric valve means 4 and 5. A suitable circuit controlling means, such as a switch 6, may be connected in series relation with the transformer 3 and the electric valves 4 and 5. The electric valves 4 and 5 may be of the type employing an ionizable medium, such as a gas or a vapor, and each comprises an anode 1, a cathode 8 which may be of the self-reconstructing type such as mercury, and an associated control member 9 of the make-alive or immersionigniter type comprising a material having a relatively high specific electrical resistivity, such as boron-carbide or silicon-carbide.

I employ excitation circuits l0 and II which are associated with electric Valves 4 and 5, respectively, and which serve to effect energization of the immersion-igniter control members 9. Each of the excitation circuits In and H includes a control electric valve l2 which is connected between the anode 1 of the associated valve and the immersion-igniter control member 9, through a current limiting resistance I3. The electric valves l2 are preferably of the type employing an ionizable medium and each comprises a control member 14. In order to impress on the control members M a negative unidirectional biasing potential which tends to maintain the electric valves nonconductive except during those intervals when it is desired to ignite the electric valves 4 and 5, I employ capacitances l5 which are charged to the polarity indicated by means of a transformer l 6 which is energized from the alternating current circuit 2 and by means of unidirectional conducting devices ll which are connected in series relation with secondary windings of transformer I6 and the associated capacithe control valves l2 conductive and hence to render electric valves 4 and 5 conductive, I employ impedance elements, such as resistances 2|. These resistances are connected in series relation with the respective associated capacitances l5 and resistances I8.

I employ a circuit 22 for generating a voltage a of peaked wave form to effect the desired energization of the resistances 2| in excitation circults I0 and H. The voltage appearing across the terminals of resistances 2| in response to the energization provided by circuit 22 is, of course, of peaked wave form, effecting precise control of electric valves I2. The circuit 22 is disclosed and claimed in a copending patent application Serial No. 138,809 of Harold W. Lord, filed April 24, 1937, and assigned to the assignee of the present application. The circuit 22 comprises a transformer 23 which is preferably of the type designed to provide a voltage of peaked wave form and may be of the self-saturating type. The circuit also includes a pair of unidirectional conducting devices 24 which are connected in series relation with an electric discharge device 25 of the controlled type including a control member 26. The unidirectional conducting devices 24 and the electric discharge device 25 act in series relation to transmit current to primary winding 28 of transformer 21. Due to the fact that the voltages induced in the secondary windings of transformer 23 are of peaked wave form, the controlled electric discharge device 25 is effective to control the number of half cycles of current transmitted to the transformer 21 in accordance.

with the control potential appearing across the conductors 29 and 3B which constitute a control circuit. A current limiting resistance 3| may be connected in series relation with control member 26 of the discharge device 25. As a means for controlling the amount of energy transmitted to load circuit I during the intervals of time estab lished by the timing circuits described hereinafter, a phase shifting device, such as a rotary phase shifter 32, may be interposed between the alternating current supply circuit 2 and the primary winding of transformer 23. By adjustment of the rotary phase shifter 32, the time of starting of the electric valves 4 and 5 during the positive half cycles of applied anode-cathode voltage is controllable.

I employ a polarity selector and a wave selector 33 which control the time of initiation of electric discharges in the electric valves 4 and 5. The polarity selector 33 may be of the type disclosed and claimed in a copending application Serial No. 146,019 of Harold W. Lord, filed June 2, 1937, and assigned to the assignee of the present application. The polarity selector 33 makes it possible to initiate consecutive energizations of the load circuit l during half cycles of voltage of the same polarity or during half cycles of opposite polarity. The polarity selector 83 may comprise a source of direct current including conductors 34 and. As a means of generating the unidirectional voltage, I employ a full wave rectifier 38 including a pair of unidirectional conducting devices such as electric valves 31, a transformer 38 and a smoothing reactance 38. A voltage divider is connected across the conductors 34 and 35 and comprises a resistance 48 having intermediate terminals "-44. A second voltage divider mayaiso be connected across the conductors 34 and 35 and may comprise serially connected resistances 45 and 48, the latter being tion 51, is employed to produce a control voltage when a nonconducting discharge device of the discharge devices 48 and 49 is rendered conductive. The intermediate connection 55 of primary winding 54 is connected to the positive conductor 34. Resistances 58 and 59 are connected in series relation with electric discharge devices 48 and 49, respectively, and are connected at a common point 60, completing the parallel paths of the polarity selector. Point 88 is connected to the negative terminal of the direct current source through a parallel connected capacitance 81 and a resistance Gi -which serve as a means for producing an additional biasing voltage in circuit 33. As a commutating means for the electric discharge devices 48 and 48, I employ capacitances 53 and 64, the former being permanently connected across the parallel paths and the latter being arranged to be selectively connected across or disconnected from the parallel paths.

A contactor 85 may be connected in series relation with one of the electric discharge devices 48 or 49, such as discharge device 48 to start the circuit in the event the circuit fails to commutate when operation is initiated.

As a means for controlling the electric discharge devices 48 and 49 for uni-polar or antipolar starting, that is, to control the times of initiation of the electrical impulses so that consecutive energizations of the load circuit I occur during half cycles of the same or opposite polarities of the voltage of supply circuit 2, I employ an excitation circuit 88 and this circuit includes a transformer 81 and a switch 88 which in the right-hand position initiates consecutive impulses which occur during half cycles of voltage of like polarity of circuit 2 and which in the left-hand position generate consecutive impulses which occur during half cycles of opposite polarity of the voltage of circuit 2. Secondary windings. 88 of transformer 81 are shunted by adjustable resistances l8 and capacitances H are connected in series relation with the control members 52 of the electric discharge devices 48 and 48. To impress unidirectional potentials on the control members 52 of the discharge devices 48 and 48, I employ a voltage divider comprising a pair of resistances 12 having a common juncture l3 As a means for controlling the ratio of theintervals of conduction to the intervals of nonconduction of the electric valves 4 and '5, or in other words as an agency for controlling the welding cycle, or to control the interval of a single energization, I employ a circuit 14 which is responsive to the electrical impulse generated by the polarity selector 33. This feature of employing-two electric circuits, one for controlling the time at which the energizations of the welding circuit begin and the other for controlling the welding cycle, is disclosed and broadly claimed in a joint patent application Serial No. 146,020 of Louis G. Levoy, Jr. and G. W. Garman, filed June 2, 1937, Patent No. 2,166,305, dated July 18, 1939, and assigned to the assignee of the present application. The circuit I4 is also energized from the direct current source including conductors 34 and 35, and includes a capacitance '15 which is energized therefrom. An electric valve 18, which is preferably of the type employing an ionizable medium, periodically discharges the capacitance to generate a second timing quantity. The electric valve '18 includes an anode IT, a cathode I8 and a control member 19. An inductance 88 may be connected in series relation with the electric valve 18 to assist in rendering the electric valve nonconductive. A capacitance 81 may be connected across the cathode 18 and the control member 19 to absorb extraneous transient voltages; and a current limiting resistance 82 may be connected in series relation with the control member, 19. The electric valve 18 is rendered conductive by means of the electrical quantity or control voltage generated by the polarity selector 33. The output voltage of transformer 53 appearing across the terminals of secondary winding 56 is rectified by means of a pair of unidirectional conducting devices, such as electric valves 83, and the unidirectional current is transmitted through a suitable impedance element such as a resistance 84. A suitable controlling means, such as a contactor 85, may be connected across the terminals of the resistance 84 to increase the voltage impressed on the control member 19 of electric valve 18. A resistance 85 is connected in series relation with resistance 84 and the left-hand terminal of the resistance 88 is connected to theintermediate connection 44 of resistance 48 in the voltage divider. A par- 88 are employed to control the voltage impressed on the control member 19 of the electric valve 18 so that the control voltage is of peaked wave form. A unidirectional conducting device, such as an electric valve 89, is connected between cathode 18 of electric valve 18 and intermediate connection 43 of resistance 48. Electric valve 89' serves to limit the maximum voltage and charge of capacitance 15, and thereby make the charge on capacitance 15 substantially independent of time after valve 89 becomes conducting. These features are disclosed and claimed in my copending patent application Serial No. 146,021 filed June 2, 1937, Patent No. 2,166,306, dated July 18, 1939, and assigned to the assignee of the present application.

An adjustable resistance 98 is connected in series relation with the electric valve 18 and the negative terminal of the direct current source including conductors and 34. This element allel connected resistance -81 and a capacitance I.

the electric valves 4 and 5 where the system is operating to effect a predetermined number of consecutive energizations of the load circuit I from the supply circuit 2. Where the system is operating'to effect only a single energization of the'load circuit I, such as during spot welding operations, the resistance is a. means for adjusting the period of energization of the load circuit I.

I provide a lockout circuit 9I which is arranged to impress a negative potential at point 12 in the polarity selector circuit to maintain the then nonconducting valve in a nonconducting condition so that the interval of energization of the load circuit I is accurately determinable or so that the number of energizations of the load circuit I is accurately determinable. The lockout circuit 9I includes an electric discharge device 92 which is preferably of the type employing an ionizable medium, such as a gas or a vapor, and comprises an anode 93, a cathode 94, and a control member 95. A current limiting resistance is connected in series relation with the control member 95. A capacitance 99 may be connected across the control member 95 and the cathode 94 to absorb transient voltages. A capacitance 91 impresses a negative unidirectional biasing potential on the control member 95 tending to maintain the electric discharge device 92 in a nonconducting condition, and the capacitance 91 is charged to the polarity indicated by means of a unidirectional conducting device 91' and transformer 91" which is energized from the alternating current circuit 2. In order to render the electric discharge device 92 conductive at the expiration of a precisely determinable in terval of time, I provide a circuit which is energized from a source of alternating current and may include a serially connected capacitance 99, a rectifier 99 and a controlled electric valve I00. The rectifier 99 is energized from the alternating current circuit 2 and comprises a transformer IM and may comprise a full wave rectifying valve I02. A current limiting resistance I03 is connected in series relation with the electric valve I00. Electric valve I00 is preferably of the type employing an ionizable medium and includes a control member I04.

I provide a suitable adjustable impedance, such as an adjustable resistance I05, which is connected in series relation with the capacitance 99, the rectifier 99, and electric valve I00 to control the rate at which the capacitance 98 is charged and hence to control the time interval at which the electric discharge device 92 is rendered conductive. A suitable controlling means, such as a contactor I06, may be connected across the terminals of the resistance I05 and may be arranged to be closed when it is desired to eiIect only a single energization of the welding circuit I. A discharge circuit including a resistance I01 and a contactor I08 is provided for the capacitance 98 to serve as a means for resetting the lockout circuit. The contactor I09 may be arranged to be normally biased to the closed circuit position and the contactor I00 may be normally biased to the open circuit position.

In the event it is desired to use the circuit 33 for only unipolar starting and where it is desired to transmit only an even number of impulses of current to the load circuit I, the capacitance 99 may be charged from the alternating current circuit 2 directly through the controlled electric valve I0l, thereby dispensing with the necessity for the rectifier 99. When-the lockout circuit 9| is so arranged, the electric valve III transmits halt cycles of current to the capacitance 99 from circuit 2 through the resistance I05. Of course, with this arrangement the circuit 9| accurately determines the period of energization of the load circuit I by transmitting current during only half cycles -of one polarity of the alternating current circuit 2.

To impress on the control member I04 of the electric valve I00 a negative unidirectional biasing potential tending to maintain this valve in a nonconducting condition, I provide a capacitance I09 which is charged to the polarity indicated by a unidirectional conducting device H0 and a transformer III which is connected to the alternating current circuit 2. A current limiting resistance II2 is provided in series relation with control member I04. The electric valve I00 is rendered conductive in response to a predetermined controlling influence such as the timing voltage generated by the circuit I4, and the control member I04 is connected to conductor 30 through a capacitance II3. The output voltage of the circuit 14 is impressed on the control member I04 through a circuit including the capacitance H3 and an impedance element such as a resistance II4 which is connected in series relation with capacitance H9. The cathode 94 of the electric discharge device 92 is connected to the negative conductor 35 of the direct current source through a conductor II5. Capacitance H6 is connected across control member I04 and cathode of electric valve I00 to absorb transient voltages.

As a means for selectively disconnecting and connecting the electric discharge device 92 in circuit with the control members 52 of electric discharge devices 48 and 49, I provide a suitable circuit controlling means such as a switch or contactor III. The contactor III also serves to render the electric discharge device 92 nonconductive by opening the anode-cathode circuit. As an additional means for rendering the discharge device 92 nonconductive, I provide a circuit including a resistance III! and a contactor II9 which in conjunction with the switch III serve to close a circuit across the anode and cathode of the electric discharge device 92. A capacitance I20 is connected in series relation with resistance II9 to serve as a means for absorbing transients occasioned by the opening and closing of contactor II 9. A resistance I2I is connected in series relation with resistance II! and is connected to intermediate connection 41 of resistance 46.

I provide switches I22, I23 and I24 for controlling or presetting the control system so that the load circuit I may be energized in a variety of diiierent ways. For example, the switches I2I-I23 are arranged to have three separate positions, each corresponding to a different type of energization of the load circuit I. In the lefthand position, the switches are arranged to effect energization of the load circuit I during a single interval of time; in the intermediate position the switches control the system to effect a predetermined consecutive number of energizations of the load circuit I; and in the right-hand position the switches control the system to effect an indefinite number of periodic energizations oi. the load circuit. It is to be understood that each of these energizations may comprise a fraction of a single halt cycle of current, a complete halt cycle of current, or a predetermined number of complete or fractional half cycles of cur- 7 rent. Switches I22-I24 may be arranged to be operated simultaneously or may be arranged to operate in a desired sequence. In the arrangement shown in the drawing, the switches are represented as being mechanically coupled and are arranged to be operated simultaneously. The movable elements of switches I22 and I23 are connected to point I3 in the polarity selector circuit 33 through a conductor I25. Switch I22, when in the left-hand position, connects point ,13 in the polarity selector circuit 33 to intermediate connection 41 of resistance 46 through resistances H8 and I2I. Of course, when the contactor H9 is closed, point I3 is also connected to the negative conductor 35 of the direct current source. Switch I22, when in the intermediate and right-hand positions, connects point I3 to a voltage divider I26 which in turn is connected across intermediate connections ll and 42 of resistance 40. The voltage divider I26 serves as a means for controlling the welding cycle, or, in other words, as a means for controlling the sum of the intervals of conduction and the intervals of nonconduction of the electric valves 4 and 5 when the system is performing interrupted-spot and seam welding operations. Switch I23, when in the left-hand and intermediate positions, presets the circuit for spot welding and inter.- rupted-spot welding operations and when the contactor II! is in the closed circuit position connects points I3 to the negative conductor 35 of the direct current source through electric discharge device 92. Switch I24, when in the intermediate and right-hand positions, connects the additional commutating capacitance 04 across the parallel paths of the polarity selector 33. It is to be noted that the electric discharge device 92 is connectedin circuit nly for the spot welding and the interrupted-spot welding operations, and that this element is not employed where it is desired to use the system for seam welding. The contactors I08 and H9 may be arranged to be opened simultaneously by a control switch or other suitable means to place the circuit in condition for spot and interrupted-spot welding operations. Furthermore, the contactor I" may be arranged to be closed simultaneously with the opening of contactors I08 and H9. As a further matter, it is to be understood that the contactor 85 may be closed simultaneously with the operation of contactors I00, II! and H0. These controls may be effected by the usual devices employing control switches and electromagnetic devices.

The operation of the embodiment of my invention shown in the single figure of the drawing will be explained by considering the system when it is desired to effect energization of the load circuit I from the alternating current circuit 2 through the electric valves and 5. Of course, the switch 6 is moved to the closed circuit position. The electric valves I and conduct current to energize transformer 3. The amount of energy transmitted to the load circuit I de pends upon the time during the positive half cycles of applied anode-cathode voltage at which the electric valves are rendered conductive. The amount of energy transmitted to the load circuit I is maximum when the electric valves are rendered conductive at a point during the positive half cycles of applied anode-cathode voltage corresponding to the power-factor angle of the load circuit, and the amount of energy transmitted to the circuit I-decreases as the valves r rendered conductive at later points in the positive half cycles. Control electric valves I2 are rendered conductive to energize the immersion-igniter control members 9 of electric valves 4 and 5 during predetermined intervals established by the control system, the positive impulses of voltage for igniting the valves I2 being provided by the circuit 22 and are introduced intoexcitation circuits I0 and II by resistances 2|.

The circuit 22 transmits a predetermined number of impulses of voltage of peaked wave form depending upon the periodic voltage impressed across the control member 20 and the cathode of the electric discharge device 25 byv means of conductors 29 and 30. The phase of the peaks of voltage produced by circuit 22 relative to the voltage of circuit 2 is controllable by the positioning of the rotary phase shifter 32, thereby providing a suitable means for controlling the time of energization of the immersionigniter control members 0 during the positive half cycles of voltage applied to the anodes I of electric valves 4 and 5. In other words, circuit 22 controls the amount of energy transmitted to. the load circuit I during the intervals of time established by the timing circuits.

The polarity selector or wave selector 33 controls the time of the initiation of the periodic control voltage and hence controls the time of initiation of the arc discharges within electric valves 4 and 5. In welding circuits it is frequently desirable to begin consecutive or succeeding energizations of the load circuit during half cycles of voltage of opposite polarity to'avoid a saturation condition of the associated transformer apparatus so that the load current, or the current transmitted by the electric valves, does not exceed a safe operating range. When the switch 68 of the polarity selector 33 is in the lefthand position, the circuit is arranged so that consecutive impulses of the timing voltage are commenced or initiated during half cycles of voltage of opposite polarity of the alternating current source 2. The parallel paths of the polarity selector 33, each of which includes one of the electric discharge devices 48 and 49, are arranged so that one of the paths is always conducting and is arranged so that the control voltage is initiated when a nonconducting electric discharge means is rendered conductive. When the switch 68 is in the right-hand position, the consecutive impulses of voltage generated by the polarity selector 33 are initiated during half cycles of voltage of like polarity of circuit 2.

Of course, it is to be understood that when the system is operating to transmit a predetermined number of impulses of the timing voltage, the. circuit 33 controls the periodicity of these impulses and the circuit ll controls the ratio of the intervals of conduction to the intervals of nonconduction of the electric discharge device 25,. and thereby controls the ratio of the intervals of conduction to the interval of nonconduction of the electric valves I and 5. This condition of operation, of course, corresponds to the interrupted-spot welding operation. When the system is employed for spot welding, the polarity selector 33 controls the time of initiation of the periodic timing voltage produced by circuit I4, and the circuit II controls the actual interval of conduction of the electric discharge device 25 in circuit 22 andthe'reby controisthe period of energization of the load circuit I. The amount of energy transmitted during the respective intervals of conduction is controlled by adjustment of the rotary phase shifter 32 in circuit 22.

The circuit I4, which generates a periodic voltage, or a single impulse of voltage, or a predetermined number of impulses of voltage, depending upon the setting of switches I22-I2I, impresses these control voltages on control member 25 of electric discharge device 25 through conductors 29 and 30. The duration, period or periodicity of the single impulse or the number of impulses generated by circuit I4 is different from the period or periodicity of the supply circuit 2.

Thelockout circuit 9|, which is efiectively connected in circuit for the spot welding and interrupted-spot welding operations, serves to eifect energization of the load circuit I during accurately determinable intervals of time and effects this control by impressing a negative potential on point I3 in the polarity selector circuit 33 at the expiration of such interval of time. The manner in which this lockout circuit 0| functions may be explained by considering the system when it is arranged for spot welding operation, that is, when the system is arrangedto effect a single energization of the load circuit I. This single energization of the load circuit I may correspond to a fractional half cycle of voltage of the supply circuit 2, or may correspond to a complete half cycle of voltage of the supply circuit 2, or may correspond to a predetermined number of complete or fractional half cycles of voltage of the supply circuit 2. Let it be assumed that the switches I22I24 are in the position indicated in he drawing, that is, in the spot welding preset lOSllJlOll. To place the system in condition for operation, contactor I08 is moved to the open circuit position, contactors 85; I05 and III are moved to the closed circuit positions and contactor H9 is opened to initiate the welding op- :ration. If the switch 68 is in the left-hand position so that the circuit is arranged for antipolar starting, circuit 33 will operate to produce an impulse of voltage during a half cycle of voltage of circuit 2 of the proper polarity, and the voltage appearing across the resistance 84 will be of sufiicient magnitude to render electric valve I8 conductive. Upon being rendered conductive, the capacitance I5 will discharge through electric valve I6 to produce an impulse of voltage which will render electric valve 25 conductive for a desired interval of time, the length of which depends principally upon the setting of the adjustable resistance 90. The lockout circuit 9| operates to prevent the generation of a subsequent impulse in the following manner. .The impulse of voltage generated by circuit I4 is impressed upon control member I04 of the electric valve I00 through capacitance I I3 and resistance II4 so that electric valve I00 is rendered conductive, thereby charging the capacitance 98 through a circuit including the secondary winding of transformer IOI, electric valve I02, electric valve I00 and contactor I06. The charge accumulated in capacitance 58 is of the polarity tending to overcome the effect of the negative biasing potential produced by capacitance 81 and renders the electric discharge device 82 conductive. When the electric discharge device 92 is rendered conductive, a negative potential is impressed on point I3 of the polarity selector 33 through a circuit including conductor II5, electric discharge device 82, contactor I", switch I23 and conductor I25. This negative biasing potential prevents the discharge device of discharge devices 08 and from being rendered conductive, and thereby prevents the initiation of a subsequent impulse. The circuit may be reset by closing contactor I08 which closes the discharge circuit ior capacitance 88, and by closing contactor II9 which closes a circuit across the anode and cathode of electric discharge device 92, thereby rendering the discharge device nonconductive. The circuit is then in condition for a subsequent spot welding operation, which may be initiated by opening contactors I08 and I I8.

It is to be noted that since the rectifier 89 is energized from the alternating current circuit 2, the charging of the capacitance 98 and hence the control of the electric discharge device 82 is substantially independent of the magnitude of the control voltage provided by circuit I4 and independent of the settings of circuits 33 and II. 0f course, the electric valve I00 is responsive to the number of impulses and the duration of the impulses generated by circuit I0.

Where it is desired to effect a predetermined number of consecutive energizations of the load circuit I, as in interrupted-spot welding operations, the switches I22--I24 are moved to the intermediate positions. The lockout circuit BI is effectively connected in circuit for this operation, but the contactor I08 is maintained in the open circuit position so that the adjustable resistance I05 controls the rate at which the charge is established on capacitance 38. Ccntactor is maintained in the closed posit onhe pol selector 33 under this condition of operation controls the periodicity of the successive energizations of the load circuit I, and also controls the time of initiation of the consecutive energizations. The voltage divider I26 may be adjusted to control the welding cycle, that is, to control the sum of the intervals of conduction and the intervals of nonconduction. In response to each impulse generated by the polarity selector 33, the circuit I4 generates a periodic voltage which controls the ratio of the intervals of conduction to the intervals of nonconduction oi electric discharge device 25 in circuit 22, and hence controls the ratio of the intervals of conduction to the intervals of nonconduction of electric valves 4 and 5. When in the intermediate position, switch I24 may be utilized to connecttheadditionalcommutating capacitance 64 across the parallel paths of circuit 33. Since the resistance I05 is connected in series relation with capacitance 88, the rate at which the capacitance is charged is substantially less than that under spot welding operation so that the lockout circuit does not become effective until the desired number of impulses have been transmitted by the circuit I4. Upon the transmission of the desired number of impulses, electric discharge device 82 will be rendere'd conductive to impress a negative biasing potential on point 13 to prevent the generation of subsequent impulses, thereby eflecting the desired number of periodic energizations of the load circuit I durin the desired interval of time. Of course. it is to be understood that during the interrupted-spot welding operation the contactors I08 and II! are in the open positions, and the contactor 85 and contactor III are in the closed circuit positions. To reset the circuit, contactor I08 is closed and contactor 85 is opened. Another series of energizations of circuit I may be initiated by opening contactors I08 and by closing contactors III and 85.

Where it is desired to elfect periodic energization of the load circuit I continuously, the switches I22-I2| are moved to the right-hand positions. This condition is sometimesdeflned as a seam welding operation and the lockout circuit 9| is not connected to the control system. The voltage divider I26 may be adjusted to control the welding cycle, that is, to control the sum of the periods of conduction to the periods oi'nonconduction, or. in other words, to control the periods of energization of'the load circuit I, and the resistance 90 may be adjusted to control the ratio of the intervals of conduction to the intervals of 'nonconduction. In addition, the rotary phase shifter 32 may be adjusted to control the amount of energy transmitted during each period of conduction of the electric valves 4 and 5.

While I have shown and described my invention as applied to a particular system of connections and as embodying various devices diagrammatically shown, it will be obvious to those skilled in the art that changes and modifications may be made without departing from my invention, and I, therefore, aim in the appended claims to cover all such changes and modifications as fall within the true spirit and scope of my invention.

What I claim as new and desire to secure by Letters Patent the United States, is:

1. In combination, an alternating current supply circuit, a load circuit, electric translating apparatus interposed therebetween and comprising an electric valve means having a control member, means for energizing said control member comprising a control circuit for generating an electrical quantity to render said electric valve means conductive during an interval of time or predetermined length, and lock-out means connected between said electric valve meansand said control circuit for rendering said control circuit inoperative at the end of said interval and comprising an electric discharge device, means tending to maintain said discharge device nonconductive, a capacitance and a seriall connected rectifier energized from said supply circuit and a controlled electric valve responsive to said electrical quantity for charging said capacitance to render said discharge device conductive.

2. In combination, an alternating current supply circuit, .a load circuit, electric translating apparatus interposed therebetween and comprising an electric valve means having a control member, means for energizing said control member to render said electric valve means conductive during an interval of time of predetermined length and comprising an electric discharge device, said electric discharge device comprising a control electrode for controlling the conductivity thereof, and lock-out means connected between said electric valve means and said electric discharge device for rendering said discharge device nonconductive at the end of said interval and comprising a second electric discharge device, a control circuit tending to maintain said second discharge device nonconductive, a capacitance and a serial- 1y connected rectifier energizeddfrom said supply circuit and a controlled electric valve for charging said capacitance to render said second discharge device conductive in response to the conduction of said first mentioned electric discharge device.

3. In combination, an alternating current circuit, an electric discharge device having a control member, means for producing a timing voltage comprising a source of direct current, capacitance means to be charged from said source and an electric valve for discharging said capacitance,

means for controlling the value of said capacitance means to'control the period of said timing voltage, means for impressing on said control member a biasing potential tending to maintain said discharge devicefnonconductive, and means for rendering said discharge device conductive at the expiration of a predetermined interval oi.

time comprising in series relation a second capacitance and a controlled electric valve responsive to said timing voltage for charging said second capacitance from said alternating current circuit during an interval of time established by said timing voltage.

4. In combination, an alternating current circuit, an electric discharge device having an anode. a cathode and a control member, means for impressing on said control member a biasing potential tending to maintain said discharge device nonconductive, means for impressing on said control member a potential in opposition to the first-mentioned potential to render said discharge device conductive comprising in series relation a capacitance, a rectifier energized from said alternating current circuit and an electric valve having a control member which is energized in response to a predetermined number of electrical impulses, and circuit interrupting means connected in the anode-cathode circuit of said electric discharge device for rendering said device nonconductive after the occurrence of said predetermined number of electrical impulses.

5. In combination, an alternating current circuit, an electric discharge device having an anode, a cathode and a control member, means for impressing on said control member a biasing potential tending to maintain said discharge device nonconductive, means for impressing on said control member a potential in opposition to the first-mentioned potential to render said discharge device conductive comprising in series relation a capacitance, a rectifier energized from said alternating current circuit and an electric valve having a control member which is energized in response to a predetermined number of electrical impulses, a dischargecircuit for said capacitance, and circuit interrupting means connected in the anode-cathode circuit of said discharge device for rendering said discharge device nonconductive after the occurrence of said predetermined number of electrical impulses.

6. In combina ion, an alternating current circuit, an electric ischarge device having an anode, a cathode and a control member, means for impressing on said control member a biasing potential tending to maintain said discharge device nonconductive, means for energizing said control member to render said discharge device conductive comprising in series relation a capacitance, a rectifier energized from said alternating current circuit and an electric valve having a control member which is energized in accordance with a predetermined controlling influence, a discharge circuit for said capacitance, a circuit connected across said anode and said cathode for rendering said electric discharge device non-- conductive, and means for closing said discharge circuit and said last mentioned circuit.

7. In combination, an alternating current cirductive comprising in series relation a capacitance, a rectifier energized from said alternating current circuit and an electric valve having a control member which is energized in accordance with a. predetermined controlling influence for charging said capacitance, a discharge circuit for said capacitance comprising a normally closed contactor, contactor means connected in the anode-cathode circuit of said electric discharge device and being biased to maintain normally said discharge device in a nonconducting condition, means for opening the contactor in said discharge circuit and said c'ontactor means to place said discharge device in condition for operation, and means for closing said discharge circuit and operating said contactor means to render said discharge device nonconductive.

8. In combination, an alternating current circuit, a source of direct current, a voltage divider connected across said source of direct current, means energized from said source of direct current for generating an electrical quantity and comprising an electric discharge device having a control member, means for energizing said control member to initiate the generation 01 said electrical quantity, a second electric discharge device for impressing on said control member a negative potential derived fromsaid voltage d1- vider to render the first mentioned discharge device nonconductive after the generation of said electrical quantity, said second discharge device including a control member for controlling the nonconductive, and means for impressing on the control member of said second discharge device apotential tending to maintain said devicenonconductive, and means for impressing on the control member oi said second discharge device a potential to render said device conductive comprising a capacitance, a' rectifier energized from said alternating current circuit and being connected in series relation with said capacitance and a controlled electric valve connected in series relation with said rectifier for charging said capacitance in response to said quantity.

9. In combination, an alternating current circuit, an electric valve having a control member, means for impressing on said control member a periodic electrical quantity to render said electric valve means conductive periodically, means for maintaining said first mentioned means inoperative after the generation of a predetermined number of impulses oi. said periodic quantity comprising an electric discharge device having a control member, and means for energizing said control member to render said discharge device conductive and comprising a capacitance, a rectifier energized from said alternating current circuit and being connected in series relation with said capacitance and a controlled electric valve energized in response to said periodic electrical quantity for charging said capacitance.

10. In combination, an alternating 'current circuit, electric translating apparatus energized from said alternating current circuit, means for controlling the energization of said translating apparatus comprising an-electric discharge device having a control member, means for generating a periodic electrical quantity and for controlling the times of initiation of the impulses of said electrical quantity, means responsive to said electrical quantity for controlling the length oi. the periods of conduction of said electric discharge device, a second electric discharge device ior controlling the number of consecutive energizations of said translating apparatus, said second discharge device having a control member for controlling the conductivity thereof,-

means for impressing on the control member of said second electricdischarge device a biasing potential tending to maintain said device nonconductive, and means comprising a controlled electric valve for energizing the control member to render said second electric discharge device' conductive in response to said periodic electrical quantity.

11. In combination, an alternating current circuit, a load ci cuit, electric valve apparatus connected between said circuits for transmitting energy therebetween, a control system for controlling said electric valve apparatus comprising a timing circuit for generating a control voltage,

a lockout circuit for determining the interval of time during which said load circuit is energized efiect continued periodic energization of said 50 load circuit comprising a switching means for selectively connecting and disconnecting the lookout circuit from the control system.

LOUIS G. LEVOY, JR.

CERTIFICATE OF comm swam", Patent No. 2,252, h1. I e February 18, 19m;

LOUIS G. mvmr, JR.

It is hereby certified that error appears in the printed specification of the above numbered patent requirihg correction as follows: Page 8, first column; line 5O, c1a11 u 8, for "rioneonductive, and" read. --conductivity thereof,--; and that the seid Letters Patent shquld be read with this correction therein that the same may cqnfom to the record of the case in the Batent Oiffice. I V I Signed and sealed this 25th day of March, A. 1). 19m.

- Henry Van Arsdale (Seal) Acting-Commissioner of Patents.

CERTIFICATE or common. Patent No. 2,252,541. I February 18, 191;.1.

LOUIS 0-. reveal, JR.

It is hereby certified that error appears in the printed specification of the above numbered patent requiring correction a; follows: Page 8, first column, line 30, clai1 n 8, forv "n'oneonductive, and read --conductivity thereof,-; and that the said Letters Patent shouldbe' read with this correction therein that the same may confom to the record of the case in the Patent Office. v

Signed and sealed this 2 1 11 day of March, A. 1). 191m.

Henry Van Arsda'le (Seal) Acting Comis sioner of Patents. 

